What are you looking for?
B1_That students have demonstrated knowledge and understanding in a field of study that is based on general secondary education, and is accustomed to finding at a level that, although with the support of advanced textbooks, also include some aspects that involve knowledge from the forefront of your field of study
B3_Students have the ability to gather and interpret relevant data (usually within their area of study), to make judgments that include reflection on relevant social, scientific or ethical issues
B4_That students can convey information, ideas, problems and solutions to both specialized and non-specialized audiences
EFB1_Ability to solve mathematical problems that may arise in engineering. Ability to apply knowledge about: linear algebra, differential and integral calculus, numerical methods, numerical algorithms, statistics and optimization
EFB2_Understanding and mastery of the concepts of fields and waves and electromagnetism, theory of electrical circuits, electronic circuits, physical principle of semiconductors and logic families, electronic and photonic devices, and their application for solving engineering problems
T2_That students have the ability to work as members of an interdisciplinary team either as one more member, or performing management tasks in order to contribute to developing projects with pragmatism and a sense of responsibility, making commitments taking into account the available resources
It is a Physics course with the purpose of familiarizing students with the concepts and physical principles related to information and communication technologies.
The learning outcomes specify the specific measure of the competencies worked on.
This subject contributes to the following learning outcomes specified for the subject to which it belongs:
Additionally, the subject also evaluates the following learning outcomes that are not present in the subject to which it belongs:
The classes will be lectures (development of the theory and practical examples), participative (conceptual questions, guided resolution of exercises) and collaborative (exhibition and defense of exercises in groups by the students, simulations, practices and work of application).
Large group classes: With a master class (theory development and examples) and a participatory part (conceptual questions and guided exercises). Evidence of learning from most expected outcomes is collected, as a guide to student self-assessment and active participation in class.
Small group classes: Collaborative instruction with the resolution and presentation of exercises in work groups. They collect evidence of learning of all the expected results through the presentation of the solutions of the exercises, and of the answers to the questions that ask students and professor.
Simulations and practices: Work with simulators or in the laboratory, with a report of results and their interpretation. They collect evidence of learning for most expected outcomes.
Application work: applications from physics to computer science and from computer science to physics (where learning results RA1, RA4 and RA10 are basically assessed).
Assessment exercises that collect evidence of general learning (RA1, RA2, RA3 and RA4), and more specific as indicated below:
Topic 1: RA5
Topic 2: RA6 and RA7
Topic 3: LO8
Topic 4: LO9
50% Assessment exercises, recoverable in case of failing the subject
15% Resolution and presentation of exercises in work groups, non-recoverable
15% Simulations and practices, non-refundable
15% Application work, non-recoverable
5% Active participation in class, recoverable through the evaluation exercises
Tipler, Paul. A .; Mosca, Gene (2010) Physics for Science and Technology. Volume 2. 6th edition. Reverted.
Serway, Raymond A .; Jewett, John W. Jr. (2005) Physics for science and engineering. 6th ed. Thomson.